• Title/Summary/Keyword: Glass Machining

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Micro-machining of Glass Air Hole using Ultrasonic Machining (초음파 가공에 의한 미세 에어홀 가공 기술)

  • 김병희;전성건;남권선;김헌영;전병희
    • Proceedings of the Korean Society of Machine Tool Engineers Conference
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    • 2004.04a
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    • pp.48-52
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    • 2004
  • Ultrasonic machining is effective for machining of extreme hard and brittle materials, including glass, ceramic, carbide, graphite. The major machining principle involves the direct hammering as well as the impact of abrasive panicles on the workpiece. Also, it involve cavitation erosion. The general workpiece is flat side. This study attempted micro hole machining of a curved surface of glass tube. Ultrasonic machining is fault of the slow machining speed. An experiment does and got 16 seconds validity machining time as increasing the processing speed. Moreover, entrance crack and surface roughness was similar both machining speed is slow and fast. Several micro hole of glass tube machined using one micro tool, but tool wear is infinitesimal.

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Fabrication of Copper Electrode Array and Test of Electrochemical Discharge Machining for Micro Machining of Glass (유리의 미세 가공을 위한 구리 전극군의 제작과 전기 화학 방전 가공 시험)

  • 정주명;심우영;정옥찬;양상식
    • The Transactions of the Korean Institute of Electrical Engineers C
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    • v.53 no.9
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    • pp.488-493
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    • 2004
  • In this paper, we present the fabrication of copper electrode array and test of electrochemical discharge machining(ECDM) for glass machining. An array of 72 Cu electrodes is used to machine Borofloat33 glass. The height and diameter of a Cu electrode are 400 $\mu\textrm{m}$ and 100 $\mu\textrm{m}$ respectively. It is fabricated by ICP-RIE, Au-Au thermo-compression bonding, and copper electroplating. Borofloat33 glass is machined by the fabricated copper electrode array in 60 seconds at 55 V. The surface roughness of the machined glass is measured and the machined glass is anodically bonded with silicon.

Chemical-assisted Ultrasonic Machining of Glass by Using HF Substitute Solution (불산대체용액을 이용한 유리의 초음파 가공)

  • 전성건;남권선;김병희;김헌영;전병희
    • Transactions of Materials Processing
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    • v.13 no.3
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    • pp.262-267
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    • 2004
  • Ultrasonic machining has been known as one of the conventional machining methods in the glass fabrication processes. In ultrasonic machining, typically, glass is removed by the impulse energy of the abrasive generated by the ultrasonic power. However, when the machining feature decrease under hundreds of micrometers, as conventional ultrasonic machining uses only the impulse energy of the abrasive, the speed of ultrasonic machining decreases significantly and the surface roughness becomes deteriorated. To overcome this size effect, the chemicals which can erode glasses, such as HF, XF, etc, are added to the slurry. The chemical-assisted ultrasonic machining method, so called, is another alternating effective way for micro machining of glasses. In previous work, we used the hydrofluoric acid (HF) as an additive chemical. But, as the HF solution is too poisonous to be used as a ultrasonic process additive, it is needed to be substituted by other safe chemicals. As results of the machinability comparison of several chemicals, the GST-500F was selected to replace the HF. The GST-500F (pH $4.0{\pm}1.0$) is non-volatile, odorless. During experimental works, it was shown that the machining rate increases 1.5 times faster than the conventional ultrasonic machining. The machining load also decreases. However, the enlargement of the hole diameter and significant tool wear are still the problems to be solved.

Characteristics of Chemical-assisted Ultrasonic Machining of Glass (화학적기법을 이용한 유리의 초음파가공 특성)

  • Kim, B.H.;Jeon, S.K.;Kim, H.Y.;Jeon, B.H.
    • Proceedings of the KSME Conference
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    • 2003.04a
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    • pp.1349-1354
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    • 2003
  • Ultrasonic Machining process is an efficient and economical means of precision machining on glass and ceramic materials. However, the mechanics of the process with respect to crack initiation and propagation, and stress development in the ceramic workpiece subsurface are still not well understood. In this research, we investigate the basic mechanism of chemical assisted ultrasonic machining(CUSM) of glass through the experimental approach. For the purpose of this study, we designed and fabricated the desktop micro ultrasonic machine. The feed is controlled precisely by using the constant load control system. During the machining experiment, the effects of HF(hydrofluoric acid) characteristics and machining condition on the surface roughness and the material removal rate are measured and compared.

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Characteristics of High-Aspect-Ratio Ultrasonic Machining of Glass (초음파에 의한 고 세장비 유리가공 특성)

  • 신용주;김헌영;장인배;김병희;전병희
    • Transactions of Materials Processing
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    • v.11 no.7
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    • pp.608-613
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    • 2002
  • An ultrasonic machining process is efficient and economical means for precision machining of glass and ceramic materials. However, the mechanism of the process with respect to the crack initiation and propagation and the stress development in the ceramic workpiece subsurface arc still not well understood. In this research, we have investigated the basic mechanism of ultrasonic machining of ultrasonic machining of glass by the experimental approach. For this purpose, we designed and fabricated the desktop micro ultrasonic machine. The feed is controlled precisely by using the constant load control system. During machining experiments, the effects of abrasive characteristics and machining conditions on the surface roughness and the material removal rate are measured and compared.

Roundness Improvement and Exit Crack Prevention in Micro-USM of Soda-Lime Glass (유리의 미세 초음파 가공 시 입구 진원도 향상 및 출구 크랙방지)

  • Hong, Ji-Hoon;Kim, Duck-Hwan;Chu, Chong-Nam;Kim, Bo-Hyun
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.31 no.10
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    • pp.1039-1045
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    • 2007
  • Ultrasonic machining (USM) is suitable for machining hard, brittle and non-conductive materials such as silicon, glass and ceramics. Usually, when micro holes are machined on glass by USM, roundness of hole entrance is poor and cracks appear around the hole exit. In this paper the machining characteristics were studied for roundness improvement and exit crack prevention. From experiments, the tool bending and the shape of tool tip affect hole roundness. When the tool tip is hemispherical, good roundness of holes was obtained. The feedrate and the rotational speed of the tool affect the exit crack. With the machining conditions of 150 rpm in spindle speed and $0.5\;{\mu}m/s$ in feedrate, micro holes with less than $100\;{\mu}m$ in diameter were machined without an exit crack.

Micro-machining inside of a transparent glass (투명유리 내부의 컬러 미세형상 가공)

  • Kim Y.M.;Yoo B.H.;Cho S.H.;Chng W.S.;Kim J.G.;Whang K.H.
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2006.05a
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    • pp.209-210
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    • 2006
  • We have successfully termed brown colored patterns inside of a transparent borosilicate glass generally known as BK7, laying the focus of near infrared Ti: sapphire femtosecond laser beam in the bulk BK7 glass. It is important to keep the laser power well below the damage threshold of BK7 in forming the color center. Thanks to the low laser power, there was no laser induced mechanical damage such as cracks or threads in the color formed area. From the absorbance spectrum and its gaussian fitting, we found the band gap of BK7, 4.21eV, and three absorption edges.

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Fabrication of Glass Microstructure Using Laser-Induced Backside Wet Etching (레이저 습식 후면 식각공정을 이용한 미세 유리 구조물 제작)

  • Kim, Bo Sung;Park, Min Soo
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.38 no.9
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    • pp.967-972
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    • 2014
  • The good light permeability and hardness of glass allow it to be used in various fields. Non-conventional machining methods have been used for glass machining because of its brittle properties. As one non-contact machining method, a laser has advantages that include a high machining speed and the fact that no tool making is required. However, glass has light permeability. Thus, the use of a laser to machine glass has limitations. A nanosecond pulse laser can be used at low power for laser-induced backside wet etching, which is an indirect method. In previous studies, a short-wave laser that had good light absorption but a high price was used. In this study, a near-infrared laser was used to test the possibility of glass micro-machining. In particular, when deeper machining was conducted on a glass structure, more problems could result. To solve these problems, microstructure manufacturing was conducted using ultrasonic vibration.

The Hole machining Characteristics of Glass Fiber Reinforced Polyester for Various Machining Conditions (가공조건 변화에 따른 유리섬유 복합재료의 홈 가공 특성)

  • 김성일
    • Proceedings of the Korean Society of Machine Tool Engineers Conference
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    • 1999.10a
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    • pp.377-380
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    • 1999
  • The experimental investigating is mainly focused on the hole machining characteristics of glass fiber reinforced polyester at different surface conditions, cutting conditions and machining methods. The entrance and exit surface holes of the glass fiber reinforced polyester is observed and the surface photographs of drilled holes is showed. The cutting force is also measured.

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Micro-machining of Glasses using Chemical-assisted Ultrasonic Machining (화학적 초음파가공을 이용한 유리의 미세가공)

  • 전성건;신용주;김병희;김헌영;전병희
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.27 no.12
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    • pp.2085-2091
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    • 2003
  • An ultrasonic machining process has been known as efficient and economical means fer precision machining of glass or ceramic materials. However, because of its complexity, the mechanism of the machining process is still not well understood. Therefore, it is hard to optimize the process parameters effectively. The conventional ultrasonic machining which uses the abrasive slurry only, furthermore, is time-consuming and gives the relatively rough surface. In order to increase the material removal rate and improve the integrity of the machined surface, we have introduced the novel ultrasonic machining technique, Chemical-assisted UltraSonic Machining(CUSM). The desktop-style micro ultrasonic machine has been developed and the z-axis feed is controlled by the constant load control algorithm. To obtain the chemical effects, the low concentration HF(hydrofluoric acid) solution, which erodes glass, added to alumina slurry. Through various experiments and comparison with conventional results, the superiority of CUSM is verified. MRR increases over 200%, the surface roughness is improved and the machining load decreases dramatically.